Faezeh Rasimarzabadi scite author profile

Faezeh Rasimarzabadi

5Publications

8Citation Statements Received

37Citation Statements Given

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Affiliations

National Research Council Canada

Publications

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An altitude capable rig for studying engine inlet velocity profile effects: Boundary layer generator

et al. 2022

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A new aerodynamic open-circuit test rig for studying boundary layer ingestion (BLI) propulsion has been developed by National Research Council of Canada. The purpose is to demonstrate the advantages of BLI in reducing the power required for a given thrust and to validate the performance of BLI fan concepts. The rig consists of a boundary layer generator to simulate boundary layer development over an aircraft fuselage. The boundary layer generator can be used to create a natural boundary layer due to skin friction but also comprises an array of perforated plates through which pressurised air can be blown to manipulate the boundary layer thickness. The size of the boundary layer thickness can be controlled upstream of the fan blades. Parametric studies of boundary layer thickness were then feasible. The test calibration was conducted to validate the concept.

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Design of a sub-scale fan for a boundary layer ingestion test with by-pass flow

et al. 2022

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A design of a sub-scale Boundary Layer Ingestion (BLI) fan for a transonic test rig is presented. The fan is intended to be used in flow conditions with varying distortion patterns representative of a BLI application on an aircraft. The sub-scale fan design is based on a design study of a full-scale fan for a BLI demonstration project for a Fokker 100 aircraft. CFD results from the full-scale fan design and the ingested distortion pattern from CFD analyses of the whole aircraft are used as inputs for this study. The sub-scale fan is designed to have similar performance characteristics to the full-scale fan within the capabilities of the test facility. The available geometric rig envelope in the test facility necessitates a reduction in geometric scale and consideration of the operating conditions. Fan blades and vanes are re-designed for these conditions in order to mitigate the effects of the scaling. The effects of reduced size, increased relative tip clearance and thicknesses of the blades and vanes are evaluated as part of the step-by-step adaption of the design to the sub-scale conditions. Finally, the installation effects in the rig are simulated including important effects of the by-pass flow on the running characteristics and the need to control the effective fan nozzle area in order to cover the available fan operating range. The predicted operating behaviour of the fan as installed in the coming transonic test rig gives strong indication that the sub-scale fan tests will be successful.

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Performance Improvement of Heat Exchangers Used in a Hybrid Electric Aircraft

Rasimarzabadi

Crain

Canteenwalla

et al. 2022

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Thermal management system analysis of a kW scale hybrid electric aircraft developed at the National Research Council of Canada (NRC) has been provided with the aim of assessing the cooling capacity and improving the efficiency. For the electric propulsion system of the aircraft, a series cooling loop has been designed that comprises a heat exchanger (radiator) and two pumps. As coolant travels through the motor and controller, it accumulates heat, then the heat is dissipated from the coolant passing through the radiator. From the calculated parameters for different demonstration flight phases of the aircraft, it is concluded that the current radiator design is limited by the air side resistance. This air thermal resistance comprises over 76% of the total thermal resistance in all flight phases. Therefore, a large frontal area to meet cooling needs is required. The potential of different methods for cooling improvement of the radiator were investigated and a new concept was suggested for heat transfer enhancement which is a passive enhancing method by applying different micro-fin roughness on the fins or coolant tubes of a radiator.

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Cooling Improvement of Gas Turbine Rotary Blades

Rasimarzabadi

Kamalimoghadam²,

Najafi

et al. 2020

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A new method is presented to improve cooling of the turbine blades by using active extraction from the compressor outlet to supply more cooling air with more energy. The cool air is extracted from the end of compressor through a set of peripheral holes to the air transferring channels on the disc edge or torque tube using the tangential velocity vector of the rotating shaft which results in increasing the amount and energy of the cooling air. In fact a forward angle of inlet holes for the channels is used to help the pressurized air overcome the air centrifugal force and to accelerate the flow going into the torque tube. To investigate the effect of new idea, both the original and proposed models are analyzed using 3D CFD simulation on a selected physical domain of a gas turbine. The compressible rotating Navier-Stokes equations are used for numerical simulation of two geometries. The governing equations, mesh treatment, boundary conditions and numerical setup are described. The calculation results are compared to those of the original turbine shaft to show the heat transfer improvement by enhancing the cooling flow rate and fluid energy.

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Cooling Improvement of Gas Turbine Rotary Blades

Rasimarzabadi¹,

Moghadam²,

Najafi³

et al. 2021

Preprint

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